Experimental investigation on the fundamental physical-layer capabilities for converged metro–access architectures using coherent transceivers

IF 4 2区计算机科学 Q1 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

Journal of Optical Communications and Networking Pub Date : 2025-07-02 DOI:10.1364/JOCN.558563

Giuseppe Rizzelli;Mariacristina Casasco;Emilio Riccardi;Annachiara Pagano;Valter Ferrero;Roberto Gaudino

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Abstract

We present a fully experimental investigation on the fundamental physical-layer capabilities of future converged metro + access architectures using commercial coherent transceivers and reconfigurable optical add-drop multiplexers (ROADMs), which are placed at the boundary between the two network segments to implement all-optical routing of upstream and downstream wavelengths. For the access part, we focus on passive optical network architectures, as they are the most commonly deployed and also the most demanding at the physical layer due to their very high loss and single fiber operation. In our experimental demonstration, we target very high bit rates (200G and 400G net data rates) and key physical-layer scalability, such as the maximum achievable optical distribution network loss as a function of available optical signal-to-noise ratio in the metro segments, ROADM internal insertion loss, and other possible impairments, like tight optical filtering or power level unbalances.

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基于相干收发器的融合城域接入体系结构基本物理层性能的实验研究

我们对未来融合城域+接入架构的基本物理层能力进行了全面的实验研究，该架构使用商用相干收发器和可重构光加丢多路复用器（roadm）， roadm位于两个网段之间的边界，以实现上下行波长的全光路由。对于接入部分，我们将重点放在无源光网络架构上，因为无源光网络架构是部署最普遍的，也是物理层要求最高的，因为它们具有非常高的损耗和单光纤操作。在我们的实验演示中，我们的目标是非常高的比特率（200G和400G网络数据速率）和关键的物理层可扩展性，例如可实现的最大光分配网络损耗（城域段中可用的光信噪比的函数），ROADM内部插入损耗以及其他可能的损害，如严格的光滤波或功率电平不平衡。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Optical Communications and Networking 工程技术-电信学

CiteScore

9.40

自引率

16.00%

发文量

104

审稿时长

4 months

期刊介绍： The scope of the Journal includes advances in the state-of-the-art of optical networking science, technology, and engineering. Both theoretical contributions (including new techniques, concepts, analyses, and economic studies) and practical contributions (including optical networking experiments, prototypes, and new applications) are encouraged. Subareas of interest include the architecture and design of optical networks, optical network survivability and security, software-defined optical networking, elastic optical networks, data and control plane advances, network management related innovation, and optical access networks. Enabling technologies and their applications are suitable topics only if the results are shown to directly impact optical networking beyond simple point-to-point networks.